Arterial elasticity evaluating device based on pulse analysis

Abstract

The invention provides an arterial elasticity evaluating device based on pulse analysis. The device comprises a left-and-right channel pulse signal detecting module, a computer and a data storage card, wherein the left-and-right channel pulse signal detecting module is connected with an analog-digital conversion module and used for collecting pulse signals of bilateral limbs of a subject; the data storage card is used for storing the pulse signals of the subject and a created arterial elasticity evaluation report; the analog-digital conversion module, the data storage card and a printer are all connected with the computer; the computer is used for performing real-time analysis on the pulse signals, displaying and storing, and printing control, as well as realizing evaluation on pulse signal quality, normalization of the pulse signals, creation and analysis of a pulse template, adjustment of wavelet characteristic parameters, arterial elasticity evaluation and creation of the evaluation report. With the adoption of the device, the pulse signals can be collected from different positions in both sides of the subject and then analyzed and treated on real time, so as to accurately evaluate the arterial elasticity of the bilateral limbs of the subject.

Description

technical field [0001] The invention relates to a device for evaluating arterial elastic function, which belongs to the technical field of non-invasive detection of human arterial elastic function. Background technique [0002] The damage of cardiovascular and cerebrovascular diseases to the human body is hidden, gradual, systemic, and has no obvious clinical symptoms, so it is called "silent disease". However, it is the number one killer of human health. According to the data released by the World Health Organization (WHO), 16 million people die from cardiovascular and cerebrovascular diseases every year in the world, accounting for more than 50% of the total mortality; The absolute number of patients with cardiovascular and cerebrovascular diseases in my country ranks first in the world. Among the causes of cardiovascular and cerebrovascular diseases, arteriosclerosis is the main cause, which is the basis of cardiovascular and cerebrovascular diseases such as hypertension,...

AI Technical Summary

Problems solved by technology

[0003] For a long time, the main technical means to evaluate the arterial elasticity function clinically is angiography, but this method is an invasive test, which requires high technical and equipment conditions, the inspection price is relatively expensive, and there may be adverse reactions related to the operation (such as contrast agent allergy and contrast agent nephropathy, etc.), these deficiencies largely affect its wide application in clinic; more importantly, invasive arteriography can only find that obvious Arterial structural lesions with stenosis of the lumen, and limited help in the detection of arterial elastic function before the arterial structural lesions

At present, there are three main methods for non-invasive detection of arterial elastic function: the first is pulse wave velocity (pulse wave velocity, PWV) measurement method, which evaluates the propagation velocity between two fixed points when the pulse wave passes through the arterial system The disadvantage of arterial elasticity is that the pulse wave propagation distance is required to calculate PWV. This distance is estimated using empirical formulas based on the subject's height and weight information. The empirical formula is based on demographic data, and it is difficult to guarantee the accuracy of individual detection; The second is to evaluate the arterial elasticity function by analyzing the pulse wave waveform and calculating the augmentation index (AI), but the calculation of the AI ​​index is very unstable and easily affected by noise, resulting in the same subject twice before and after. The measurement deviation is relatively large; the third method is to use ultrasound imaging to directly detect the compliance (compliance, C) of a specific artery wall. This detection method also requires high technical and equipment conditions, and the detection

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